Download RX64M, RX71M Group Flash Memory User`s Manual

User’s Manual
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RX64M Group, RX71M Group
Flash Memory
User’s Manual: Hardware Interface
32
RENESAS 32-Bit MCU
RX Family / RX600 Series, RX700 Series
All information contained in these materials, including products and product specifications,
represents information on the product at the time of publication and is subject to change by
Renesas Electronics Corp. without notice. Please review the latest information published by
Renesas Electronics Corp. through various means, including the Renesas Electronics Corp.
website (http://www.renesas.com).
www.renesas.com
Rev.1.10
Jan 2015
Notice
1.
Descriptions of circuits, software and other related information in this document are provided only to illustrate the operation of
semiconductor products and application examples. You are fully responsible for the incorporation of these circuits, software,
and information in the design of your equipment. Renesas Electronics assumes no responsibility for any losses incurred by you
or third parties arising from the use of these circuits, software, or information.
2.
Renesas Electronics has used reasonable care in preparing the information included in this document, but Renesas Electronics
does not warrant that such information is error free. Renesas Electronics assumes no liability whatsoever for any damages
incurred by you resulting from errors in or omissions from the information included herein.
3.
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6.
You should use the Renesas Electronics products described in this document within the range specified by Renesas Electronics,
especially with respect to the maximum rating, operating supply voltage range, movement power voltage range, heat radiation
characteristics, installation and other product characteristics. Renesas Electronics shall have no liability for malfunctions or
damages arising out of the use of Renesas Electronics products beyond such specified ranges.
7.
Although Renesas Electronics endeavors to improve the quality and reliability of its products, semiconductor products have
specific characteristics such as the occurrence of failure at a certain rate and malfunctions under certain use conditions. Further,
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(Note 2) “Renesas Electronics product(s)” means any product developed or manufactured by or for Renesas Electronics.
(2012.4)
General Precautions in the Handling of MPU/MCU Products
The following usage notes are applicable to all MPU/MCU products from Renesas. For detailed usage notes on the
products covered by this document, refer to the relevant sections of the document as well as any technical updates that
have been issued for the products.
1. Handling of Unused Pins
Handle unused pins in accordance with the directions given under Handling of Unused Pins in the
manual.
⎯ The input pins of CMOS products are generally in the high-impedance state. In operation with an
unused pin in the open-circuit state, extra electromagnetic noise is induced in the vicinity of LSI, an
associated shoot-through current flows internally, and malfunctions occur due to the false
recognition of the pin state as an input signal become possible. Unused pins should be handled as
described under Handling of Unused Pins in the manual.
2. Processing at Power-on
The state of the product is undefined at the moment when power is supplied.
⎯ The states of internal circuits in the LSI are indeterminate and the states of register settings and
pins are undefined at the moment when power is supplied.
In a finished product where the reset signal is applied to the external reset pin, the states of pins
are not guaranteed from the moment when power is supplied until the reset process is completed.
In a similar way, the states of pins in a product that is reset by an on-chip power-on reset function
are not guaranteed from the moment when power is supplied until the power reaches the level at
which resetting has been specified.
3. Prohibition of Access to Reserved Addresses
Access to reserved addresses is prohibited.
⎯ The reserved addresses are provided for the possible future expansion of functions. Do not access
these addresses; the correct operation of LSI is not guaranteed if they are accessed.
4. Clock Signals
After applying a reset, only release the reset line after the operating clock signal has become stable.
When switching the clock signal during program execution, wait until the target clock signal has
stabilized.
⎯ When the clock signal is generated with an external resonator (or from an external oscillator)
during a reset, ensure that the reset line is only released after full stabilization of the clock signal.
Moreover, when switching to a clock signal produced with an external resonator (or by an external
oscillator) while program execution is in progress, wait until the target clock signal is stable.
5. Differences between Products
Before changing from one product to another, i.e. to a product with a different part number, confirm
that the change will not lead to problems.
⎯ The characteristics of an MPU or MCU in the same group but having a different part number may
differ in terms of the internal memory capacity, layout pattern, and other factors, which can affect
the ranges of electrical characteristics, such as characteristic values, operating margins, immunity
to noise, and amount of radiated noise. When changing to a product with a different part number,
implement a system-evaluation test for the given product.
Contents
1.
Features ........................................................................................................................................... 6
2.
Module Configuration ....................................................................................................................... 7
3.
Address Space ................................................................................................................................. 8
4.
Registers .......................................................................................................................................... 9
4.1
Flash P/E Protect Register (FWEPROR) ............................................................................. 10
4.2
Flash Access Status Register (FASTAT) ............................................................................. 11
4.3
Flash Access Error Interrupt Enable Register (FAEINT) ..................................................... 13
4.4
Flash Ready Interrupt Enable Register (FRDYIE) ............................................................... 14
4.5
FACI Command Start Address Register (FSADDR) ............................................................ 15
4.6
FACI Command End Address Register (FEADDR) ............................................................. 16
4.7
FCURAM Enable Register (FCURAME) .............................................................................. 17
4.8
Flash Status Register (FSTATR) ......................................................................................... 18
4.9
Flash P/E Mode Entry Register (FENTRYR) ....................................................................... 22
4.10
Flash Protection Register (FPROTR) .................................................................................. 23
4.11
Flash Sequencer Set-Up Initialization Register (FSUINITR) ............................................... 24
4.12
Lock Bit Status Register (FLKSTAT) ................................................................................... 25
4.13
FACI Command Register (FCMDR) .................................................................................... 26
4.14
Flash P/E Status Register (FPESTAT) ................................................................................ 27
4.15
Data Flash Blank Check Control Register (FBCCNT) ......................................................... 27
4.16
Data Flash Blank Check Status Register (FBCSTAT) ......................................................... 28
4.17
Data Flash Programming Start Address Register (FPSADDR) ........................................... 28
4.18
Flash Sequencer Processing Switching Register (FCPSR) ................................................ 29
4.19
Flash Sequencer Processing Clock Notification Register (FPCKAR) .................................. 30
5.
Operating Modes of the Flash Sequencer ..................................................................................... 31
6.
FACI Commands ............................................................................................................................ 32
6.1
List of FACI Commands ....................................................................................................... 32
6.2
Relationship between the Flash Sequencer State and FACI Commands ........................... 33
6.3
Usage of FACI Commands .................................................................................................. 35
6.3.1
Overview of Command Usage in Code Flash memory P/E Mode ............................................. 35
6.3.2
Overview of Command Usage in Data Flash Memory P/E Mode ............................................. 37
6.3.3
Transferring the FCU Firmware ................................................................................................. 38
6.3.4
Transition to Code Flash Memory P/E Mode ............................................................................. 39
6.3.5
Transition to Data Flash Memory P/E Mode .............................................................................. 39
6.3.6
Transition to Read Mode ............................................................................................................ 40
6.3.7
Recovery from the Command-Locked State .............................................................................. 41
6.3.8
Programming Command ............................................................................................................. 43
6.3.9
Block Erase Command ............................................................................................................... 45
6.3.10
P/E Suspend Command .............................................................................................................. 46
6.3.11
P/E Resume Command ............................................................................................................... 51
6.3.12
Status Clear Command ............................................................................................................... 51
6.3.13
Forced Stop Command ............................................................................................................... 52
7.
6.3.14
Blank Check Command .............................................................................................................. 53
6.3.15
Configuration Set Command ...................................................................................................... 55
6.3.16
Lock-Bit Programming Command ............................................................................................. 57
6.3.17
Lock-Bit Read Command ........................................................................................................... 58
Safety Function .............................................................................................................................. 59
7.1
Software Protection ............................................................................................................. 59
7.1.1
Protection through FWEPROR .................................................................................................. 59
7.1.2
Protection through FENTRYR ................................................................................................... 59
7.1.3
Protection through Lock Bit ....................................................................................................... 59
7.2
Error Protection .................................................................................................................... 59
7.3
Boot Program Protection ..................................................................................................... 61
7.3.1
User Boot Protection .................................................................................................................. 61
8.
Usage Notes .................................................................................................................................. 62
9.
Electrical Characteristics ................................................................................................................ 63
9.1
AC Characteristics ............................................................................................................... 63
REVISION HISTORY ............................................................................................................................... 64
RX64M Group, RX71M Group Flash Memory
User’s Manual: Hardware Interface
1.
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Features
The features of the flash memory are described below. See the User’s Manual: Hardware for information on the capacity,
block configuration, and addresses of the flash memory in this MCU.
Programming/Erasure
A dedicated sequencer for the flash memory (flash sequencer) executes programming and erasure via internal peripheral
bus 6. The flash sequencer also supports the suspension or resumption of programming or erasure, and background
operations (BGO).
Security Functions
The flash memory incorporates hardware functions to prevent illicit tampering with or reading out of data in flash
memory.
Protection Functions
The flash memory incorporates hardware functions to prevent erroneous programming.
Interrupts
The flash memory supports an interrupt to indicate completion of processing by the flash sequencer and an error interrupt
to indicate operations that were in error.
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RX64M Group, RX71M Group Flash Memory
2.
2. Module Configuration
Module Configuration
Modules related to the flash memory are configured as shown in Figure 2.1. The flash sequencer is configured of the
Flash Control Unit (FCU) and Flash Application Command Interface (FACI). The FCU executes basic control of
overwriting of the flash memory. The FCURAM is RAM for the storage of firmware to control execution by the FCU.
The FACI receives FACI commands via internal peripheral bus 6 and controls FCU operations accordingly.
In response to a reset, the FACI transfers data from the flash memory to the option-setting memory.
Flash sequencer
FCURAM
(4 KB)
FIFERR
FRDYI
FCU
Flash sequencer bus
FCLK
Code
flash memory
CPU
Data
flash memory
FACI
Option-setting
memory
Internal peripheral bus 6
FCU: Flash Control Unit
FACI: Flash Application Command Interface
Figure 2.1
Configuration of Flash Memory Related Modules
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RX64M Group, RX71M Group Flash Memory
3.
3. Address Space
Address Space
Using the hardware interface with the flash memory requires accessing to the area containing registers of the hardware,
that for the issuing of FACI commands, that for storage of the FCU firmware, and that for the FCURAM. Table 3.1
gives information on all of these areas.
Table 3.1
Information on the Hardware Interface Area
Area
Address
Capacity
Area containing the various registers of the hardware
See section 4, Registers.
See section 4, Registers.
FACI command-issuing area
007E 0000h
4 bytes
FCU firmware storage area
FEFF F000h to FEFF FFFFh
4 Kbytes
FCURAM area
007F 8000h to 007F 8FFFh
4 Kbytes
Configuration setting area
0012 0040h to 0012 007Fh
64 bytes
Refer to the User’s Manual: Hardware for information on the addresses of the flash memory.
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RX64M Group, RX71M Group Flash Memory
4.
4. Registers
Registers
This section gives information on registers to which access is required when using the hardware interface of the flash
memory. Reset registers that are not specifically mentioned to their initial states.
For information on the option-setting memory, see the User’s Manual: Hardware for the product you are using.
Table 4.1
List of Registers
Number of Access Cycles
Address
Module
Symbol
Register Name
Register
Symbol
Number Access
of Bits Size
ICLK ≥
ICLK <
Reference
PCLKB/FCLK PCLKB/FCLK Page
0008 C296h
FLASH
Flash P/E Protect Register
FWEPROR
8
8
4 to 5 PCLKB
2 to 3 ICLK
10
007F E010h
FLASH
Flash Access Status Register
FASTAT
8
8
2 to 4 FCLK
2 to 3 ICLK
11
007F E014h
FLASH
Flash Access Error Interrupt Enable Register
FAEINT
8
8
2 to 4 FCLK
2 to 3 ICLK
13
007F E018h
FLASH
Flash Ready Interrupt Enable Register
FRDYIE
8
8
2 to 4 FCLK
2 to 3 ICLK
14
007F E030h
FLASH
FACI Command Start Address Register
FSADDR
32
32
2 to 4 FCLK
2 to 3 ICLK
15
007F E034h
FLASH
FACI Command End Address Register
FEADDR
32
32
2 to 4 FCLK
2 to 3 ICLK
16
007F E054h
FLASH
FCURAM Enable Register
FCURAME
16
16
2 to 4 FCLK
2 to 3 ICLK
17
007F E080h
FLASH
Flash Status Register
FSTATR
32
32
2 to 4 FCLK
2 to 3 ICLK
18
22
007F E084h
FLASH
Flash P/E Mode Entry Register
FENTRYR
16
16
2 to 4 FCLK
2 to 3 ICLK
007F E088h
FLASH
Flash Protection Register
FPROTR
16
16
2 to 4 FCLK
2 to 3 ICLK
23
007F E08Ch
FLASH
Flash Sequencer Set-Up Initialization Register
FSUINITR
16
16
2 to 4 FCLK
2 to 3 ICLK
24
007F E090h
FLASH
Lock Bit Status Register
FLKSTAT
8
8
2 to 4 FCLK
2 to 3 ICLK
25
007F E0A0h
FLASH
FACI Command Register
FCMDR
16
16
2 to 4 FCLK
2 to 3 ICLK
26
007F E0C0h
FLASH
Flash P/E Status Register
FPESTAT
16
16
2 to 4 FCLK
2 to 3 ICLK
27
007F E0D0h
FLASH
Data Flash Blank Check Control Register
FBCCNT
8
8
2 to 4 FCLK
2 to 3 ICLK
27
007F E0D4h
FLASH
Data Flash Blank Check Status Register
FBCSTAT
8
8
2 to 4 FCLK
2 to 3 ICLK
28
007F E0D8h
FLASH
Data Flash Programming Start Address Register
FPSADDR
32
32
2 to 4 FCLK
2 to 3 ICLK
28
007F E0E0h
FLASH
Flash Sequencer Processing Switching Register
FCPSR
16
16
2 to 4 FCLK
2 to 3 ICLK
29
007F E0E4h
FLASH
Flash Sequencer Processing Clock Notification Register
FPCKAR
16
16
2 to 4 FCLK
2 to 3 ICLK
30
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RX64M Group, RX71M Group Flash Memory
4.1
4. Registers
Flash P/E Protect Register (FWEPROR)
Address(es): 0008 C296h
Value after reset:
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
FLWE[1:0]
0
0
0
0
0
0
1
0
Bit
Symbol
Bit Name
Description
R/W
b1, b0
FLWE[1:0]
Flash Programming and
Erasure
b1
R/W
0
0
1
1
b7 to b2
—
Reserved
b0
0: Prohibits programming and erasure of the code flash, data
flash, or option-setting memory, programming and erasure
of lock bits, and blank checking.
1: Permits programming and erasure of the code flash, data
flash, or option-setting memory, programming and erasure
of lock bits, and blank checking.
0: Prohibits programming and erasure of the code flash, data
flash, or option-setting memory, programming and erasure
of lock bits, and blank checking.
1: Prohibits programming and erasure of the code flash, data
flash, or option-setting memory, programming and erasure
of lock bits, and blank checking.
These bits are read as 0. The write value should be 0.
R/W
Programming and erasure of the code flash memory, data flash memory, or option-setting memory, programming and
erasure of lock bits, and blank checking are prohibited by hardware.
FWEPROR is initialized by a reset due to the signal on the RES# pin, a power-on reset, a voltage-monitoring 0 reset, an
independent watchdog timer reset, a watchdog timer reset, a voltage-monitoring 1 reset, a voltage-monitoring 2 reset,
and a software reset, and by transitions to software standby and deep software standby.
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RX64M Group, RX71M Group Flash Memory
4.2
4. Registers
Flash Access Status Register (FASTAT)
Address(es): 007F E010h
b7
b6
b5
CFAE
—
—
0
0
0
Value after reset:
b4
b3
CMDLK DFAE
0
b2
b1
b0
—
—
ECRCT
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
ECRCT
Error Flag
0: No error has occurred.
1: An error has occurred.
R
b2, b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b3
DFAE
Data Flash Memory Access
Violation Flag
0: No data flash memory access violation has occurred.
1: A data flash memory access violation has occurred.
R/W*1
b4
CMDLK
Command Lock Flag
0: The flash sequencer is not in the command-locked state.
1: The flash sequencer is in the command-locked state.
R
b6, b5
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b7
CFAE
Code Flash Memory Access
Violation Flag
0: No code flash memory access violation has occurred.
1: A code flash memory access violation has occurred.
R/W*1
Note 1. Only 0 can be written to clear the flag after 1 is read.
FASTAT register indicates whether a code flash memory or data flash memory access violation has occurred. If any of
the CFAE, CMDLK and DFAE flags is set to 1, the flash sequencer enters the command-locked state (see section 7.2,
Error Protection). To release it from the command-locked state, a status clear command or forced stop command must
be issued by the FACI after clearing the CFAE and DFAE flags in the FASTAT register to 0.
ECRCT Flag (Error Flag)
This flag indicates that a 1-bit error has been corrected in reading of the flash memory area by the flash sequencer (with
parameters for configuration setting or programming) or reading of the FCURAM.
When a 2-bit error is detected in reading of the FCURAM, CMDLK is set to 1 (the flash sequencer is in the commandlocked state) and the ECRCT flag does not change.
[Setting Conditions]
 When the flash sequencer reads the flash memory area (configuration setting and programming parameters).
 When a 1-bit error is corrected by reading the FCURAM.
[Clearing Condition]
 When the flash sequencer starts processing of a forced stop command while the FRCRCT flag in the FSTATR
register is 1.
DFAE Flag (Data Flash Memory Access Violation Flag)
This flag indicates whether a data flash memory access violation occurred. If this flag is set to 1, the FSTATR.ILGLERR
flag is set to 1, placing the flash sequencer in the command-locked state.
[Setting Conditions]
In general, commands being issued in data flash memory P/E mode as described below.
 An FACI command being issued while the setting of b18 to b0 in the FSADDR register is 1 0000h to 7 FFFFh
(indicating the reserved portion of the data area)
 A configuration setting command being issued while the setting of b18 to b0 in the FSADDR register is 0 0000h to
0 003Fh or 0 0100h to 7 FFFFh.
[Clearing Condition]
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RX64M Group, RX71M Group Flash Memory
4. Registers
 0 being written after reading of 1.
CMDLK Flag (Command Lock Flag)
This flag indicates that the flash sequencer is in the command-locked state.
[Setting Condition]
 The flash sequencer detects an error and enters the command-locked state.
[Clearing Condition]
 The flash sequencer starting to process a status clear or forced stop command while the CFAE or DFAE flag in the
FASTAT register is 0.
CFAE Flag (Code Flash Memory Access Violation Flag)
This flag indicates whether a code flash memory access violation has occurred. If this flag is set to 1, the
FSTATR.ILGLERR flag is set to 1, placing the flash sequencer in the command-locked state.
[Setting Conditions]
An FACI command being issued in code flash memory P/E mode while settings are as follows:
 The setting of b23 to b0 in the FSADDR register is 00 0000h to BF FFFFh (reserved portion of the user area).
[Clearing Condition]
 0 being written after reading of 1.
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RX64M Group, RX71M Group Flash Memory
4.3
4. Registers
Flash Access Error Interrupt Enable Register (FAEINT)
Address(es): 007F E014h
b7
b6
b5
CFAEIE
—
—
1
0
0
Value after reset:
b4
b3
CMDLK DFAEIE
IE
1
b2
b1
b0
—
—
ECRCT
IE
0
0
1
1
Bit
Symbol
Bit Name
Description
R/W
b0
ECRCTIE
Error Interrupt Enable
0: Generation of an FIFERR interrupt request is disabled when
FASTAT.ECRCT is set to 1.
1: Generation of an FIFERR interrupt request is enabled when
FASTAT.ECRCT is set to 1.
R/W
b2, b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b3
DFAEIE
Data Flash Memory Access
Violation Interrupt Enable
0: Generation of an FIFERR interrupt request is disabled when
FASTAT.DFAE is set to 1.
1: Generation of an FIFERR interrupt request is enabled when
FASTAT.DFAE is set to 1.
R/W
b4
CMDLKIE
Command Lock Interrupt
Enable
0: Generation of an FIFERR interrupt request is disabled when
FASTAT.CMDLK is set to 1.
1: Generation of an FIFERR interrupt request is enabled when
FASTAT.CMDLK is set to 1.
R/W
b6, b5
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b7
CFAEIE
Code Flash Memory Access
Violation Interrupt Enable
0: Generation of an FIFERR interrupt request is disabled when
FASTAT.CFAE is set to 1.
1: Generation of an FIFERR interrupt request is enabled when
FASTAT.CFAE is set to 1.
R/W
FAEINT register enables or disables generation of a flash access error (FIFERR) interrupt request.
ECRCTIE Bit (Error Interrupt Enable)
This bit enables or disables generation of an FIFERR interrupt request when a 1-bit error has been corrected in reading of
the flash memory area by the flash sequencer (with parameters for configuration setting or programming) or reading of
the FCURAM, leading to setting of the FASTAT.ECRCT flag to 1.
DFAEIE Bit (Data Flash Memory Access Violation Interrupt Enable)
This bit enables or disables generation of an FIFERR interrupt request when a data flash memory access violation occurs
leading to the FASTAT.DFAE flag being set to 1.
CMDLKIE Bit (Command Lock Interrupt Enable)
This bit enables or disables generation of an FIFERR interrupt request when the flash sequencer enters the commandlocked state leading to the FASTAT.CMDLK flag being set to 1.
CFAEIE Bit (Code Flash Memory Access Violation Interrupt Enable)
This bit enables or disables generation of an FIFERR interrupt request when a code flash memory access violation occurs
leading to the FASTAT.CFAE flag being set to 1.
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RX64M Group, RX71M Group Flash Memory
4.4
4. Registers
Flash Ready Interrupt Enable Register (FRDYIE)
Address(es): 007F E018h
Value after reset:
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
FRDYI
E
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FRDYIE
Flash Ready Interrupt Enable
0: Generation of an FRDY interrupt request is disabled.
1: Generation of an FRDY interrupt request is enabled.
R/W
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FRDYIE register enables or disables generation of a flash ready (FRDY) interrupt request.
FRDYIE Bit (Flash Ready Interrupt Enable)
This bit is used to enable or disable generation of an FRDY interrupt request when the FASTAT.FRDY flag is changed
from 0 to 1 on completion of processing by the flash sequencer of programming and erasure or a blank checking
command.
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RX64M Group, RX71M Group Flash Memory
4.5
4. Registers
FACI Command Start Address Register (FSADDR)
Address(es): 007F E030h
b31
b30
b29
b28
b27
b26
b25
b24
b23
b22
b21
b20
b19
b18
b17
b16
FSADDR[31:16]
Value after reset:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
0
0
0
0
0
0
0
FSADDR[15:0]
Value after reset:
0
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
b31 to b0
FSADDR
[31:0]
Start Address for FACI
Command Processing
[Command]
Programming (code flash memory):
Programming (data flash memory):
Block erase (code flash memory):
Block erase (data flash memory):
Blank check:
Configuration setting:
Lock-bit programming:
Lock-bit read:
R/W
[Address boundary]
256-byte
4-byte
8-Kbyte or 32-Kbyte
64-byte
4-byte
16-byte
8-Kbyte or 32-Kbyte
8-Kbyte or 32-Kbyte
R/W*1
Note 1. Writing to these bits is only possible when the FSTATR.FRDY flag is 1. Writing to these bits while the FSTATR.FRDY flag = 0 is
ignored. Note that b0 and b1 are read-only.
FSADDR register specifies the address where the target area for command processing starts when the FACI command
for programming, block erasure, blank checking, configuration setting, lock-bit programming, or lock-bit reading is
issued.
The FSADDR register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
FSADDR[31:0] Bits (Start Address for FACI Command Processing)
These bits specify the start address for FACI command processing. b31 to b24 are ignored in FACI command processing
for the code flash memory. b31 to b19 are ignored in FACI command processing for the data flash memory. Bits
corresponding to address bits of lower order than the corresponding boundary listed above are also ignored.
Refer to the User's Manual: Hardware for the start addresses of the code flash memory area and data flash memory area.
See Table 6.5, Address Used by Configuration Set Command for the start address of the configuration set area
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RX64M Group, RX71M Group Flash Memory
4.6
4. Registers
FACI Command End Address Register (FEADDR)
Address(es): 007F E034h
b31
b30
b29
b28
b27
b26
b25
b24
b23
b22
b21
b20
b19
b18
b17
b16
FEADDR[31:16]
Value after reset:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
0
0
0
0
0
0
0
FEADDR[15:0]
Value after reset:
0
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b31 to b0
FEADDR
[31:0]
End Address for FACI
Command Processing
The end address for FACI command processing
R/W*1
Note 1. Writing to these bits is only possible when the FSTATR.FRDY flag is 1. Writing to these bits while the FSTATR.FRDY flag = 0 is
ignored. Note that b0 and b1 are read-only.
FEADDR register specifies the address where the target area for blank check command processing ends. When
incremental mode is selected as the addressing mode for blank checking (i.e. when FBCCNT.BCDIR = 0), the address
specified in the FSADDR register should be smaller than the address in the FEADDR register. Conversely, the address in
the FSADDR register should be larger than the address in the FEADDR register when decremental mode is selected as
the addressing mode for blank checking (i.e. when FBCCNT.BCDIR = 1). If the settings of the FBCCNT.BCDIR bit and
the FSADDR and FEADDR registers are inconsistent with the above rules, the flash sequencer enters the commandlocked state (see section 7.2, Error Protection).
The FEADDR register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
FEADDR[31:0] Bits (End Address for FACI Command Processing)
These bits specify the end address for blank check command processing. b31 to b19, b1, and b0 are ignored in command
processing.
Refer to the User's Manual: Hardware for the end address of the data flash memory area.
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RX64M Group, RX71M Group Flash Memory
4.7
4. Registers
FCURAM Enable Register (FCURAME)
Address(es): 007F E054h
b15
b14
b13
b12
b11
b10
b9
b8
KEY[7:0]
0
Value after reset:
0
0
0
0
0
0
0
b7
b6
b5
b4
b3
b2
—
—
—
—
—
—
0
0
0
0
0
0
b1
b0
FRAMT FCRME
RAN
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FCRME
FCURAM Enable
0: Disables access to the FCURAM.
1: Enables access to the FCURAM.
R/W*1
b1
FRAMTRAN
FCURAM Transfer Mode
0: Normal transfer mode
Both read and write access to the FCURAM are possible.
1: High-speed write mode
Only high-speed write access to the FCURAM is possible.
R/W*1
b7 to b2
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b15 to b8
KEY[7:0]
Key Code
Key code
R/W*2
Note 1. Writing to these bits is only possible when 16 bits are written and the value written to the KEY bits is C4h.
Note 2. Written values are not retained by these bits. These bits are read as 0.
FCURAME register enables or disables access to the FCURAM area.
FCRME Bit (FCURAM Enable)
This bit enables or disables access to the FCURAM. Before writing to the FCURAM, stop the flash sequencer by
clearing the FENTRYR register to 0000h.
FRAMTRAN Bit (FCURAM Transfer Mode)
This bit specifies the FCURAM transfer mode.
KEY[7:0] Bits (Key Code)
These bits control permission and prohibition of writing to the FRAMTRAN and FCRME bits.
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RX64M Group, RX71M Group Flash Memory
4.8
4. Registers
Flash Status Register (FSTATR)
Address(es): 007F E080h
Value after reset:
b31
b30
b29
b28
b27
b26
b25
b24
b23
b22
b21
b20
b19
b18
b17
b16
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
0
0
0
0
FRDY ILGLER ERSER PRGER SUSRD DBFUL ERSSP PRGSP FCUER FLWEE
R
R
R
Y
L
D
D
R
RR
1
Value after reset:
0
0
0
0
0
0
0
0
0
FRDTC FRCRC
T
T
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FRCRCT
1-Bit Error Correction Monitor Flag
0: A 1-bit error correction has not been detected.
1: A 1-bit error correction has been detected.
R
b1
FRDTCT
2-Bit Error Detection Monitor Flag
0: A 2-bit error has not been detected.
1: A 2-bit error has been detected.
R
b5 to b2
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b6
FLWEERR
Flash Write/Erase Protect Error Flag
0: An error has not occurred.
1: An error has occurred.
R
b7
FCUERR
FCU Error Flag
0: An error has not occurred during FCU processing.
1: An error has occurred during FCU processing.
R
b8
PRGSPD
Programming Suspend Status Flag
0: The flash sequencer is in a state other than those
corresponding to the value 1.
1: The flash sequencer is in the programming suspension
processing state or the programming suspended state.
R
b9
ERSSPD
Erasure Suspend Status Flag
0: The flash sequencer is in a state other than those
corresponding to the value 1.
1: The flash sequencer is in the erasure suspension
processing state or the erasure-suspended state.
R
b10
DBFULL
Data Buffer Full Flag
0: The data buffer is empty.
1: The data buffer is full.
R
b11
SUSRDY
Suspend Ready Flag
0: The flash sequencer cannot receive P/E suspend
commands.
1: The flash sequencer can receive P/E suspend
commands.
R
b12
PRGERR
Programming Error Flag
0: Programming has been completed successfully.
1: An error has occurred during programming.
R
b13
ERSERR
Erasure Error Flag
0: Erasure has been completed successfully.
1: An error has occurred during erasure.
R
b14
ILGLERR
Illegal Command Error Flag
0: The flash sequencer has not detected an illegal FACI
command or illegal flash memory access.
1: The flash sequencer has detected an illegal FACI
command or illegal flash memory access.
R
b15
FRDY
Flash Ready Flag
0: Programming, block erase, P/E suspend, P/E resume,
forced stop, blank check, configuration setting, lock-bit
programming, or lock-bit read command processing is in
progress.
1: None of the above is in progress.
R
Reserved
These bits are read as 0. The write value should be 0.
R/W
b31 to b16 —
FSTATR register indicates the state of the flash sequencer.
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RX64M Group, RX71M Group Flash Memory
4. Registers
FRCRCT Flag (1-Bit Error Correction Monitor Flag)
This flag indicates that a 1-bit error has been corrected by reading FCURAM by the FCU. When the FRCRCT flag is 1,
the flash sequencer is not in the command locked state.
[Clearing Condition]
 When the flash sequencer starts processing of a forced stop command.
After the FCU is initialized by issuing a forced stop command, reload the FCU firmware into the FCURAM.
FRDTCT Flag (2-Bit Error Detection Monitor Flag)
This flag indicates that a 2-bit error has been detected by reading FCURAM by the FCU. When the FRDTCT flag is 1,
the flash sequencer is in the command locked state.
[Clearing Condition]
 When the flash sequencer starts processing of a forced stop command.
After the FCU is initialized by issuing a forced stop command, reload the FCU firmware into the FCURAM.
FLWEERR Flag (Flash Write/Erase Protect Error Flag)
This flag indicates a violation of the flash memory overwrite protection setting in the FWEPROR register. If this flag is
1, the flash sequencer is in the command-locked state.
[Clearing Condition]
 The flash sequencer starts processing of a forced stop command.
FCUERR Flag (FCU Error Flag)
This flag indicates that an error has occurred during FCU processing. If this flag is 1, the flash sequencer is in the
command-locked state.
[Clearing Condition]
 The flash sequencer starts processing of a forced stop command.
When this flag is 1, issue a forced stop command and initialize the FCU, and then reload the FCU firmware into the
FCURAM.
PRGSPD Flag (Programming Suspend Status Flag)
This flag indicates that the flash sequencer is in the programming suspension processing state or programming suspended
state.
[Setting Condition]
 The flash sequencer starts processing in response to a programming suspend command.
[Clearing Conditions]

Reception of the P/E resume command by the flash sequencer
(after write access to the FACI command-issuing area is completed).
 The flash sequencer starts processing of a forced stop command.
ERSSPD Flag (Erasure Suspend Status Flag)
This flag indicates that the flash sequencer is in the erasure suspension processing state or erasure suspended state.
[Setting Condition]
 The flash sequencer starts processing in response to an erasure suspend command.
[Clearing Conditions]

Reception of the P/E resume command by the flash sequencer
(after write access to the FACI command-issuing area is completed).
 The flash sequencer starts processing of a forced stop command.
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RX64M Group, RX71M Group Flash Memory
4. Registers
DBFULL Flag (Data Buffer Full Flag)
This flag indicates the state of the data buffer when a programming command is issued. The FACI incorporates a buffer
for write data (data buffer). When data for writing to the flash memory are issued to the FACI command-issuing area
while the data buffer is full, the FACI inserts a wait cycle in the peripheral bus 6.
[Setting Condition]
 The data buffer becomes full while programming commands are being issued.
[Clearing Condition]
 The data buffer becomes empty.
SUSRDY Flag (Suspend Ready Flag)
This flag indicates whether the flash sequencer can receive a P/E suspend command.
[Setting Condition]
 After starting programming/erasure processing, the flash sequencer enters a state in which P/E suspend commands
can be received.
[Clearing Conditions]
 Reception of the P/E suspend command or forced stop command by the flash sequencer (after write access to the
FACI command-issuing area is completed).
 During programming or erasure, the flash sequencer enters the command-locked state.
 Programming or erasure has been completed.
PRGERR Flag (Programming Error Flag)
This flag indicates the result of programming of the flash memory. If this flag is 1, the flash sequencer is in the
command-locked state.
[Setting Conditions]
 An error occurs during programming.
 A programming or lock-bit programming command is issued for an area where the lock bit setting is for protection.
[Clearing Condition]
 The flash sequencer starts processing of a status clear or forced stop command.
ERSERR Flag (Erasure Error Flag)
This flag indicates the result of erasure of the flash memory. If this flag is 1, the flash sequencer is in the commandlocked state.
[Setting Conditions]
 An error has occurred during erasure.
 A block erase command is issued for an area where the lock bit setting is for protection.
[Clearing Condition]
 The flash sequencer starts processing of a status clear or forced stop command.
ILGLERR Flag (Illegal Command Error Flag)
This flag indicates that the flash sequencer has detected an illegal FACI command or flash memory access. If this flag is
1, the flash sequencer is in the command-locked state.
[Setting Conditions] (See section 7.2, Error Protection)
 The flash sequencer has detected an illegal command.
 The flash sequencer has detected illegal flash memory access.
 The setting of the FENTRYR register is invalid.
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RX64M Group, RX71M Group Flash Memory
4. Registers
[Clearing Condition]
 The flash sequencer starts processing of a status clear or forced stop command while the DFAE and CFAE flag in
the FASTAT register is 0.
If the flash sequencer completes processing of a status clear or forced stop command while the CFAE or DFAE flag in
the FASTAT register is 1, this flag is set to 1. This flag is temporarily set to 0 during processing of a forced stop
command, and is re-set to 1 when the CFAE or DFAE flag is detected as 1 on completion of command processing.
FRDY Flag (Flash Ready Flag)
This flag indicates the command processing state of the flash sequencer.
[Setting Conditions]
 The flash sequencer completes command processing.
 The flash sequencer receives a P/E suspend command and suspends programming of the flash memory.
 The flash sequencer has received a forced stop command and ended command processing.
[Clearing Conditions]
 The flash sequencer has received an FACI command.
 For programming and configuration setting, the first write access to the FACI command-issuing area.
 For other commands, the last write access to the FACI command-issuing area.
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RX64M Group, RX71M Group Flash Memory
4.9
4. Registers
Flash P/E Mode Entry Register (FENTRYR)
Address(es): 007F E084h
b15
b14
b13
b12
b11
b10
b9
b8
KEY[7:0]
0
Value after reset:
0
0
0
0
0
0
0
b7
b6
b5
b4
b3
b2
b1
b0
FENTR
YD
—
—
—
—
—
—
FENTR
YC
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FENTRYC
Code Flash Memory P/E Mode
Entry
0: Code flash memory is in read mode.
1: Code flash memory is in P/E mode.
R/W*1, *2
b6 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b7
FENTRYD
Data Flash Memory P/E Mode
Entry
0: Data flash memory is in read mode.
1: Data flash memory is in P/E mode.
R/W*1, *2
b15 to b8
KEY[7:0]
Key Code
Key code
R/W*3
Note 1. Writing to these bits is only possible when the FSTATR.FRDY flag is 1. Writing to these bits while the FSTATR.FRDY flag = 0 is
ignored.
Note 2. Writing to these bits is only possible when 16 bits are written and the value written to the KEY bits is AAh.
Note 3. Written values are not retained by these bits. These bits are read as 0.
FENTRYR is used to specify code flash memory P/E mode and data flash memory P/E mode. To specify code flash
memory P/E mode or data flash memory P/E mode so that the flash sequencer can receive FACI commands, set either the
FENTRYD or FENTRYC bit to 1 to place the flash sequencer in P/E mode.
Note that setting this register to a value other than 0001h and 0080h, the FSTATR.ILGLERR flag will be set to 1, leading
to the flash sequencer being placed in the command-locked state.
The FENTRYR register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
FENTRYC Bit (Code Flash Memory P/E Mode Entry)
This bit specifies the P/E mode for code flash memory.
[Setting Condition]
 1 being written to the FENTRYC bit while writing to FENTRYR is enabled and FENTRYR is 0000h.
[Clearing Conditions]
 8 bits being written to FENTRYR while the FSTATR.FRDY flag is 1.
 A value other than AAh is specified in the KEY bits and 16 bits are written to FENTRYR while the
FSTATR.FRDY flag is 1.
 0 being written to the FENTRYC bit while writing to FENTRYR is enabled.
 FENTRYR being written to while writing to FENTRYR is enabled and the value of FENTRYR is other than 0000h.
FENTRYD Bit (Data Flash Memory P/E Mode Entry)
This bit specifies the P/E mode for data flash memory.
[Setting Condition]
 1 being written to the FENTRYR.FENTRYD bit while writing to FENTRYR is enabled and FENTRYR is 0000h.
[Clearing Conditions]
 8 bits being written to FENTRYR while the FSTATR.FRDY flag is 1.
 Writing of 16 bits to FENTRYR with a value other than AAh specified for the KEY bits while the FSTATR.FRDY
flag is 1.
 0 being written to the FENTRYD bit while writing to FENTRYR is enabled.
 FENTRYR being written to while writing to FENTRYR is enabled and the value of FENTRYR is other than 0000h.
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RX64M Group, RX71M Group Flash Memory
4. Registers
KEY[7:0] Bits (Key Code)
These bits control permission and prohibition of writing to the FENTRYD and FENTRYC bits.
4.10
Flash Protection Register (FPROTR)
Address(es): 007F E088h
b15
b14
b13
b12
b11
b10
b9
b8
KEY[7:0]
0
Value after reset:
0
0
0
0
0
0
0
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
FPROT
CN
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FPROTCN
Lock Bit Protection Cancel
0: Enables protection by the lock bits.
1: Disables protection by the lock bits.
R/W*1
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b15 to b8
KEY[7:0]
Key Code
Key code
R/W*2
Note 1. Writing to these bits is only possible when 16 bits are written and the value written to the KEY bits is 55h.
Note 2. Written values are not retained by these bits. These bits are read as 0.
FPROTR enables or disables protection by the lock bits of the code flash memory against programming and erasure. The
FPROTR register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
FPROTCN Bit (Lock Bit Protection Cancel)
This bit enables or disables protection by the lock bits of the code flash memory against programming and erasure.
[Setting Condition]
 1 being written to the FPROTCN bit while writing to FPROTR is enabled and the value of FENTRYR is other than
0000h.
[Clearing Conditions]
 8 bits being written to FPROTR
 Writing of 16 bits to FPROTR with a value other than 55h specified for the KEY bits
 0 being written to the FPROTRCN bit while writing to FPROTR is enabled
 The value of FENTRYR being 0000h
KEY[7:0] Bits (Key Code)
These bits control permission and prohibition of writing to the FPROTCN bit.
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RX64M Group, RX71M Group Flash Memory
4.11
4. Registers
Flash Sequencer Set-Up Initialization Register (FSUINITR)
Address(es): 007F E08Ch
b15
b14
b13
b12
b11
b10
b9
b8
KEY[7:0]
0
Value after reset:
0
0
0
0
0
0
0
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
SUINIT
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
SUINIT
Set-Up Initialization
0: The FEADDR, FPROTR, FCPSR, FSADDR, FENTRYR,
and FBCCNT flash sequencer set-up registers keep their
current values.
1: The FEADDR, FPROTR, FCPSR, FSADDR, FENTRYR,
and FBCCNT flash sequencer set-up registers are
initialized.
R/W*1, *2
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
b15 to b8
KEY[7:0]
Key Code
Key code
R/W*3
Note 1. Writing to these bits is only possible when the FSTATR.FRDY flag is 1. Writing to these bits while the FSTATR.FRDY flag = 0 is
ignored.
Note 2. Writing to these bits is only possible when 16 bits are written and the value written to the KEY bits is 2Dh.
Note 3. Written values are not retained by these bits. This bit is read as 0.
FSUINITR is used for initialization of the flash sequencer set-up.
SUINIT Bit (Set-Up Initialization)
This bit initializes the following flash sequencer set-up registers.
 FEADDR
 FPROTR
 FCPSR
 FSADDR
 FENTRYR
 FBCCNT
KEY[7:0] Bits (Key Code)
These bits control permission and prohibition of writing to the SUINIT bit.
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RX64M Group, RX71M Group Flash Memory
4.12
4. Registers
Lock Bit Status Register (FLKSTAT)
Address(es): 007F E090h
Value after reset:
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
FLOCK
ST
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
FLOCKST
Lock Bit Status Flag
0: Protected state
1: Non-protected state
R
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FLOCKST Flag (Lock Bit Status Flag)
This flag reflects the state of a lock bit as read by executing a lock-bit read command. When the FSTATR.FRDY flag
becomes 1 after the lock-bit read command is issued, the value of the target lock bit is stored in the FLOCKST flag. The
value of the FLOCKST flag is retained until the next lock-bit read command is completed.
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RX64M Group, RX71M Group Flash Memory
4.13
4. Registers
FACI Command Register (FCMDR)
Address(es): 007F E0A0h
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
CMDR[7:0]
1
Value after reset:
1
1
1
1
b3
b2
b1
b0
1
1
1
PCMDR[7:0]
1
1
1
1
1
1
1
1
Bit
Symbol
Bit Name
Description
R/W
b7 to b0
PCMDR[7:0]
Precommand Flag
The command immediately before the latest command is
stored.
R
b15 to b8
CMDR[7:0]
Command Flag
The latest command is stored.
R
FCMDR records the two most recent commands accepted by the FACI.
PCMDR[7:0] Flags (Precommand Flag)
These flags indicate the command received immediately before the latest command received by the FACI.
CMDR[7:0] Flags (Command Flag)
These flags indicate the latest command received by the FACI.
Table 4.2
States of FCMDR after Receiving Commands
Command
CMDR
PCMDR
Programming
E8h
Previous command
Block erase
D0h
20h
P/E suspend
B0h
Previous command
P/E resume
D0h
Previous command
Status clear
50h
Previous command
Forced stop
B3h
Previous command
Blank check
D0h
71h
Configuration setting
40h
Previous command
Lock-bit programming
D0h
77h
Lock-bit read
D0h
71h
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RX64M Group, RX71M Group Flash Memory
4.14
4. Registers
Flash P/E Status Register (FPESTAT)
Address(es): 007F E0C0h
Value after reset:
b15
b14
b13
b12
b11
b10
b9
b8
—
—
—
—
—
—
—
—
0
0
0
0
0
0
0
0
b7
b6
b5
b4
b3
b2
b1
b0
0
0
0
PEERRST[7:0]
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b7 to b0
PEERRST
[7:0]
P/E Error Status Flag
00h: No error
01h: Programming error due to an area being protected by its lock bit
02h: Programming error for reasons other than lock-bit protection
11h: Erasure error due to an area being protected by its lock bit
12h: Erasure error for reasons other than lock-bit protection
R
b15 to b8
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FPESTAT indicates the result of programming or erasure of the flash memory.
PEERRST[7:0] Flags (P/E Error Status Flag)
These flags indicate the source of an error that occurred during processing for the programming or erasure of the code
flash memory or data flash memory. The value of these flags is only valid if the ERSERR or PRGERR flag in the
FSTATR register is 1 while the FSTATR.FRDY flag is 1. When the ERSERR and PRGERR flags are 0, these flags retain
their value to indicate the source of the last error to have occurred.
4.15
Data Flash Blank Check Control Register (FBCCNT)
Address(es): 007F E0D0h
Value after reset:
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
BCDIR
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
BCDIR
Blank Check Direction
0: Blank checking is executed from lower addresses to higher
addresses (incremental mode).
1: Blank checking is executed from higher addresses to lower
addresses (decremental mode).
R/W
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FBCCNT specifies the addressing mode in processing of a blank check command.
The FBCCNT register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
BCDIR Bit (Blank Check Direction)
This bit specifies the addressing mode for blank checking.
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RX64M Group, RX71M Group Flash Memory
4.16
4. Registers
Data Flash Blank Check Status Register (FBCSTAT)
Address(es): 007F E0D4h
Value after reset:
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
BCST
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
BCST
Blank Check Status Flag
0: The target area is in the non-programmed state (i.e. is blank; the
area has been erased but has not yet been re-programmed).
1: The target area has been programmed with 0s or 1s.
R
b7 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FBCSTAT stores the results of checking in response to a blank check command.
BCST Flag (Blank Check Status Flag)
This flag indicates the results of checking in response to a blank check command.
4.17
Data Flash Programming Start Address Register (FPSADDR)
Address(es): 007F E0D8h
Value after reset:
b31
b30
b29
b28
b27
b26
b25
b24
b23
b22
b21
b20
b19
b18
b17
b16
—
—
—
—
—
—
—
—
—
—
—
—
—
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
0
0
0
0
0
0
0
PSADR[18:16]
PSADR[15:0]
1
Value after reset:
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
b18 to b0
PSADR[18:0]
Programmed Area Start Address
The address of the first programmed area
R
Reserved
These bits are read as 0. The write value should be 0.
R/W
b31 to b19 —
Description
R/W
FPSADDR indicates the address of the first programmed area to be found in processing of a blank check command.
PSADR[18:0] Bits (Programmed Area Start Address)
These bits indicate the address of the first programmed area to be found in processing of a blank check command. The
address is an offset from the address where the data flash memory starts. The setting of these bits is only effective if the
FBCSTAT.BCST flag is 1, while the FSTATR.FRDY flag is 1. When the FBCSTAT.BCST flag is 0, the PSADR bit holds
the address produced by the previous check.
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RX64M Group, RX71M Group Flash Memory
4.18
4. Registers
Flash Sequencer Processing Switching Register (FCPSR)
Address(es): 007F E0E0h
Value after reset:
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
b4
b3
b2
b1
b0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
ESUSP
MD
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
Symbol
Bit Name
Description
R/W
b0
ESUSPMD
Erasure Suspend Mode
0: Suspension priority mode
1: Erasure priority mode
R/W
b15 to b1
—
Reserved
These bits are read as 0. The write value should be 0.
R/W
FCPSR is for selecting the erasure suspension mode.
The FCPSR register is initialized when the FSUINITR.SUINIT bit is set to 1. It is also initialized by a reset.
ESUSPMD Bit (Erasure Suspend Mode)
This bit is for selecting the erasure suspension mode when a P/E suspend command is issued while the flash sequencer is
executing erasure processing (see section 6.3.10, P/E Suspend Command). This bit should be set before issuing a
block erase command.
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RX64M Group, RX71M Group Flash Memory
4.19
4. Registers
Flash Sequencer Processing Clock Notification Register (FPCKAR)
Address(es): 007F E0E4h
b15
b14
b13
b12
b11
b10
b9
b8
b7
b6
b5
KEY[7:0]
Value after reset:
0
0
0
0
0
b4
b3
b2
b1
b0
0/1
0/1
0/1
PCKA[7:0]
0
0
0
0/1
0/1
0/1
0/1
0/1
Bit
Symbol
Bit Name
Description
R/W
b7 to b0
PCKA[7:0]
Flash Sequencer Operating
Clock Notification
These bits are used to set the operating frequency of the
flash sequencer while processing FACI commands.
R/W*1, *2
b15 to b8
KEY[7:0]
Key Code
Key code
R/W*3
Note 1. Writing to these bits is only possible when the FSTATR.FRDY flag is 1. Writing to these bits while the FSTATR.FRDY flag = 0 is
ignored.
Note 2. Writing to these bits is only possible when 16 bits are written and the value written to the KEY bits is 1Eh.
Note 3. Written values are not retained by these bits. These bits are read as 0.
FPCKAR specifies the operating frequency of the flash sequencer while processing FACI commands. The highest
operating frequency for the given product is set as the initial value.
PCKA[7:0] Bits (Flash Sequencer Operating Clock Notification)
These bits specify the operating frequency of the flash sequencer while processing FACI commands. Set the desired
frequency in these bits before issuing an FACI command. Specifically, convert the frequency represented in MHz into a
binary number and set it in these bits.
Example: Frequency is 35.9 MHz (PCKA = 24h)
Round up the first decimal place of 35.9 MHz to a whole number (= 36) and convert it into a binary number.
If the value set in these bits is smaller than the actual operating frequency of the flash sequencer, the flash memory
overwriting characteristics cannot be guaranteed. If the value set in these bits is greater than the actual operating
frequency of the flash sequencer, the flash memory overwriting characteristics can be guaranteed but the FACI command
processing time such as the time overwriting takes will increase. The minimum FACI command processing time is
obtained when the operating frequency of the flash sequencer is the same as the value of the PCKA bit.
KEY[7:0] Bits (Key Code)
These bits control permission and prohibition of writing to the PCKA bit.
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RX64M Group, RX71M Group Flash Memory
5.
5. Operating Modes of the Flash Sequencer
Operating Modes of the Flash Sequencer
The flash sequencer has three operating modes as shown in Figure 5.1. Transitions between modes are initiated by
changing the value of the FENTRYR register.
When the value of the FENTRYR register is 0000h, the flash sequencer is in read mode. In this mode, it does not receive
FACI commands. The code flash memory and data flash memory are both readable.
When the value of the FENTRYR register is 0001h, the flash sequencer is in code flash memory P/E mode where the
code flash memory can be programmed or erased by FACI commands. In this mode, the data flash memory is not
readable. In addition, the code flash memory is not readable if background operation (BGO) is disabled. If BGO is
enabled, the code flash memory is readable. As for the condition for enabling BGO, refer to the User’s Manual:
Hardware.
When the value of the FENTRYR register is 0080h, the flash sequencer is in data flash memory P/E mode where the data
flash memory can be programmed or erased by FACI commands. In this mode, the data flash memory is not readable.
However, the code flash memory is readable.
FEN
Readable area in read mode:
Code flash memory
Data flash memory
R
TRY
T
FEN
R=
RY
FEN
TRY
R
FEN
TR
YR
Figure 5.1
h
001
=0
0h
000
=0
=0
Readable area in
code flash memory P/E mode:
Code flash memory
(under the condition in
which BGO is possible)
000
h
080
h
Readable area in
data flash P/E mode:
Code flash memory
Modes of the Flash Sequencer
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RX64M Group, RX71M Group Flash Memory
6.
FACI Commands
6.1
List of FACI Commands
Table 6.1
6. FACI Commands
List of FACI Commands
FACI Command
Description
Programming
This is used to program the user area and data area.
Units of programming are 256 bytes for the user area and 4 bytes for the data area.
Block erase
This is used to erase the user area, lock bits, or data area.
The unit of erasure is one block.
P/E suspend
This suspends programming or erasure processing.
P/E resume
This resumes suspended programming or erasure processing.
Status clear
This initializes the ILGLERR, ERSERR, and PRGERR flags in the FSTATR register and releases the
flash sequencer from the command-locked state.
Forced stop
This forcibly stops processing of FACI commands and initializes the FSTATR register.
Blank check
This is used to check if data areas are blank.
Units of blank checking: 4 bytes to 64 Kbytes (specified in 4-byte units).
Configuration setting
This is used to set the ID, security function, option-setting memory, and trusted memory (TM) function.
Units of setting: 16 bytes.
Lock-bit programming
This is used to program the lock bit for a user area.
Units of programming: 1 bit (the lock bit for one block)
Lock-bit read
The lock bit for a user area is read and the result is stored in the FLKSTAT register.
Units of programming: 1 bit (the lock bit for one block)
The FACI commands are issued by writing to the FACI command-issuing area (see Table 3.1). When write access as
shown in Table 6.2 proceeds in the specified state, the flash sequencer executes the processing corresponding to the
given command (see section 6.2, Relationship between the Flash Sequencer State and FACI Commands).
Table 6.2
FACI Command Formats
FACI Commands
Programming (user area)
256-byte programming, N = 128
Number of
Write
Access
Data to be Written to the FACI Command-Issuing Area
1st Access
2nd Access
3rd to (N+2)th
Access
(N+3)th Access
131
E8h
80h (= N)
WD1 to WD128
D0h
N+3
E8h
02h (= N)
WD1 to WDN
D0h
Block erase
2
20h
D0h
—
—
P/E suspend
1
B0h
—
—
—
P/E resume
1
D0h
—
—
—
Status clear
1
50h
—
—
—
Forced stop
1
B3h
—
—
—
Blank check
2
71h
D0h
—
—
Configuration setting
N=8
11
40h
08h (= N)
WD1 to WD8
D0h
Lock-bit programming
2
77h
D0h
—
—
Lock-bit read
2
71h
D0h
—
—
Programming (data area)
4-byte programming: N = 2
Note:
WDN (N = 1, 2,…): Nth 16-bit data to be programmed.
The flash sequencer clears the FSTATR.FRDY flag to 0 at the start of processing of a command other than the status
clear command and sets this bit to 1 on completion of command processing.
If the setting of the FRDYIE.FRDYIE bit is 1, a flash ready (FRDY) interrupt is generated when the FSTATR.FRDY flag
is set to 1.
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RX64M Group, RX71M Group Flash Memory
6.2
6. FACI Commands
Relationship between the Flash Sequencer State and FACI Commands
The sets of FACI commands that can be accepted in each of the modes/states of the flash sequencer are fixed. FACI
commands should be issued after the transition of the flash sequencer to the code flash memory P/E mode or data flash
memory P/E mode and checking of the state of the flash sequencer. Use the FSTATR and FASTAT registers to check the
state of the flash sequencer. In addition, the occurrence of errors in general can be checked by reading the
FASTAT.CMDLK flag; its value is the logical OR of the ILGLERR, ERSERR, PRGERR, FCUERR, FRDTCT, and
FLWEERR flags in the FSTATR register.
Table 6.3 lists the available commands in each operating mode.
Table 6.3
Operating Mode and Available Commands
Operating Mode
FENTRYR Register Value
Available Commands
Read mode
0000h
None
Code flash memory P/E mode
0001h
Programming
Block erase
P/E suspend
P/E resume
Status clear
Forced stop
Lock-bit programming
Lock-bit read
Data flash memory P/E mode
0080h
Programming
Block erase
P/E suspend
P/E resume
Status clear
Forced stop
Blank check
Configuration setting
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RX64M Group, RX71M Group Flash Memory
6. FACI Commands
Table 6.4 shows the state of the flash sequencer and acceptable FACI commands. An appropriate mode is assumed to
have been set before the commands are executed.
Processing of Configuration Setting
Processing to Suspend Programming or Erasure
Blank checking or lock bit reading
Programming Suspended
Erasure Suspended
Programming while Erasure is Suspended
Command-Locked State (FRDY = 1)
Command-Locked State (FRDY = 0)
Lock-Bit Programming
Processing of Forced Stop Command
Other State
Acceptable FACI Commands and the State of the Flash Sequencer
Processing of Programming or Erasure
Table 6.4
FRDY flag
0
0
0
0
1
1
0
1
0
0
0
1
SUSRDY flag
1
0
0
0
0
0
0
0
0
0
0
0
ERSSPD flag
0
0
0/1
0/1
0
1
1
0/1
0/1
0
0
0
PRGSPD flag
0
0
0/1
0/1
1
0
0
0/1
0/1
0
0
0
CMDLK flag
0
0
0
0
0
0
0
1
1
0
0
0
Programming
×
×
×
×
×
○
*3
×
×
×
×
×
○
Block erase
×
×
×
×
×
×
×
×
×
×
×
○
P/E suspend
○
×
×
×
×
×
×
—
×
×
×
—
P/E resume
×
×
×
×
○
○
×
×
×
×
×
×
Status clear
×
×
×
×
○
○
×
○
×
×
×
○
Forced stop
○
○
○
○
○
○
○
○
○
○
○
○
Blank check
×
×
×
×
○
*1
○
*1
×
×
×
×
×
○
*1
Configuration setting
×
×
×
×
×
×
×
×
×
×
×
○
*1
Lock-bit programming
×
×
×
×
×
×
×
×
×
×
×
○
*2
Lock-bit read
×
×
×
×
○
*2
○
*2, *4
×
×
×
×
×
○
*2
○: Acceptable
×: Not acceptable (places the sequencer in the command-locked state)
—: Ignored
Note 1.
Note 2.
Note 3.
Note 4.
Only acceptable in data flash memory P/E mode
Only acceptable in code flash memory P/E mode
Programming is only acceptable for blocks other than blocks where erasure has been suspended.
The value read out is undefined when a lock-bit read command is issued for a block where erasure was suspended.
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6.3
6. FACI Commands
Usage of FACI Commands
This section gives an overview of the usage of FACI commands.
6.3.1
Overview of Command Usage in Code Flash memory P/E Mode
Figure 6.1 and Figure 6.2 respectively show an overview of FACI command usage in code flash memory P/E mode for
products in which background operation (BGO) is possible and that for products in which BGO is not possible. For
which commands are available in code flash memory P/E mode, see Table 6.3.
Start
Check whether
BGO is possible
BGO is possible
BGO is not possible
Jump to the on-chip RAM
Compare the target address of the code flash memory for
reading in code flash memory P/E mode and the target address for
processing of the FACI command (specified by the FSADDR or
FEADDR register) to determine whether background operation
(BGO) is possible. For the condition in which BGO is possible,
refer to the User’s Manual: Hardware.
If the BGO function is not to be used, jump to the on-chip RAM
without confirming whether BGO is possible.
Transfer
the FCU firmware
Transfer is needed only once before using the flash sequencer.
Transition to code
flash memory P/E mode
See section 6.3.4, Transition to Code Flash Memory P/E Mode.
Set the FPCKAR register
Set this register only when the operating clock for flash sequencer is
changed and the command processing time should be optimized.
Reversing the order of the transition to code flash memory P/E mode and
the register setting does not create a problem.
FASTAT.CMDLK
flag = 1
Command lock
Recovery from
the command-locked state
Other than command lock
Issue an FACI command
Transition to read mode
End
Figure 6.1
Overview of Command Usage in Code Flash Memory P/E Mode (for products in which BGO is
possible)
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RX64M Group, RX71M Group Flash Memory
6. FACI Commands
Start
Jump to the on-chip RAM
Transfer
the FCU firmware
Transfer is needed only once before using the flash sequencer.
Transition to code
flash memory P/E mode
Set the FPCKAR register
FASTAT.CMDLK
flag = 1
Set this register only when the operating clock for flash sequencer is
changed and the command processing time should be optimized.
Reversing the order of the transition to code flash memory P/E mode
and the register setting does not create a problem.
Command lock
Issue a status clear
or forced stop command
Other than command lock
Issue an FACI command
Transition to read mode
End
Figure 6.2
Overview of Command Usage in Code Flash Memory P/E Mode (for products in which BGO is not
possible)
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RX64M Group, RX71M Group Flash Memory
6.3.2
6. FACI Commands
Overview of Command Usage in Data Flash Memory P/E Mode
An overview of FACI command usage in data flash memory P/E mode is shown below. For which commands are
available in data flash memory P/E mode, see Table 6.3.
Start
Transfer
the FCU firmware
Transfer is needed only once before using the flash sequencer.
Transition to data
flash memory P/E mode
See section 6.3.5, Transition to Data Flash Memory P/E Mode.
Set the FPCKAR register
Set this register only when the operating clock for flash sequencer is
changed and the command processing time should be optimized.
Reversing the order of the transition to data flash memory P/E mode and
the register setting does not create a problem.
FASTAT.CMDLK
flag = 1
Command lock
Issue a status clear
or forced stop command
Other than command lock
Issue an FACI command
Transition to read mode
End
Figure 6.3
Overview of Command Usage in Data Flash Memory P/E Mode
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6.3.3
6. FACI Commands
Transferring the FCU Firmware
The flash sequencer can only be used if the FCURAM holds the firmware for the FCU. The FCURAM does not hold the
FCU firmware immediately after the chip has been booted up, so the firmware must be copied from the FCU firmware
storage area to the FCURAM. Since execution of the FACI command does not update the FCURAM, if the FCU
firmware is copied only once before using the flash sequencer, re-updating of the FCURAM is not required.
As data stored in the FCURAM are undefined at boot up, writing to the FCURAM will lead to an ECC error. After
copying the FCU firmware, issue a forced stop command and then initialize the FRCRCT and FRDTCT flags in the
FSTATR register.
All processing of a forced stop command can be executed by hardware without intervention by the FCU firmware.
Start
Check the FENTRYR
register value
Other than 0000h
Write AA00h to the FENTRYR register
0000h
Write C403h or C401h
to the FCURAME register
C403h: High-speed transfer mode (write only)
C401h: Normal transfer mode (read/write)
Copy data from the FCU firmware FCU firmware storage area: Read data in 32-bit units
storage area to the FCURAM
FCURAM: Write data in 32-bit units
Write C400h
to the FCURAME register
Transition to P/E mode
Cause the transition to code flash memory P/E mode or
data flash memory P/E mode to make a forced stop
command available
Issue
a forced stop command
Clear the ECC error flag in the FCURAM
Transition to read mode
End
Figure 6.4
Flow for Transferring the FCU Firmware
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6.3.4
6. FACI Commands
Transition to Code Flash Memory P/E Mode
To use the FACI commands for the code flash memory, a transition to code flash memory P/E mode is required. To cause
the transition to code flash memory P/E mode, set the FENTRYR.FENTRYRC bit to 1.
Start
Write AA01h
to the FENTRYR register
Check that the FENTRYR register
value is 0001h
End
Figure 6.5
6.3.5
Procedure for Transition to Code Flash Memory P/E Mode
Transition to Data Flash Memory P/E Mode
To use the FACI commands for the data flash memory, a transition to data flash memory P/E mode is required. To cause
the transition to data flash memory P/E mode, set the FENTRYR.FENTRYRD bit to 1.
Start
Write AA80h to
the FENTRYR register
Check that the FENTRYR register
value is 0080h
End
Figure 6.6
Procedure for Transition to Data Flash Memory P/E Mode
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6.3.6
6. FACI Commands
Transition to Read Mode
To read the flash memory without using the BGO function, a transition to read mode is required. To cause the transition
to read mode, set the FENTRYR register to 0000h. The transition to read mode should be made after processing by the
flash sequencer is completed and while operation is in other than in the command-locked state.
Start
0
Check the FRDY flag
1
FASTAT.CMDLK flag = 1
Command lock
Timeout?*1
No
Yes
Other than command lock
Issue a status clear
or forced stop command
Issue
a forced stop command
Write AA00h to
the FENTRYR register
Check that the FENTRYR register
value is 0000h
End
Note 1. Judgment of the timeout is based on 1.1 times the maximum time for processing of the FACI command that is in
progress (see section 9, Electrical Characteristics).
Figure 6.7
Procedure for Transition to Read Mode
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6.3.7
6. FACI Commands
Recovery from the Command-Locked State
When the flash sequencer enters the command-locked state, FACI commands cannot be accepted. To release the
sequencer from the command-locked state, use the status clear command, forced stop command, or FASTAT register.
When the command-locked state is detected by checking for an error before issuing the P/E suspend command, the
FSTATR.FRDY flag may hold 0 although command processing has not been completed. If processing is not completed
within the maximum programming/erasure time specified in the User's Manual: Hardware, this can be considered a
timeout, and the flash sequencer should be stopped by the forced stop command.
When the FSTATR.ILGLERR flag is 1, check the FASTAT value. If the CFAE or DFAE flag in the FASTAT register is 1,
the status clear and forced stop commands cannot be used to release the sequencer from the command-locked state.
The FCUERR, FRDTCT, and FLWERR flags in the FSTATR register are not changed from 1 to 0 by the status clear
command. When these bits are set to 1, use the forced stop command for release from the command-locked state. The
other bits that indicate the command-locked state can be changed from 1 to 0 by the status clear or forced stop command.
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6. FACI Commands
Start
0
Check the FRDY flag
1
Check the ILGLERR flag
1
Timeout?*1
0
No
Yes
10h
CFAE = 0 and
DFAE = 0
Check
the CFAE and DFAE
flags
Issue
a forced stop command
End
Write 0 to the CFAE and DFAE
flags
Check
the FSTATR register
FCUERR = 1 or FRDTCT = 1 or FLWERR = 1
FCUERR = 0 and FRDTCT = 0 and FLWERR = 0
Issue a status clear
or forced stop command
Issue
a forced stop command
End
End
Note 1. Judgment of the timeout is based on 1.1 times the maximum time for processing of the FACI command that is in
progress (see section 9, Electrical Characteristics).
Figure 6.8
Recovery from the Command-Locked State
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6.3.8
6. FACI Commands
Programming Command
A programming command is used for writing to the user area and data area.
Before issuing a programming command, set the first address of the target block in the FSADDR register.
Writing D0h to the FACI command-issuing area at the final access of the FACI command-issuing starts the programming
command processing. If the target area of programming command processing contains the area not for writing, write
FFFFh to the corresponding area.
The FPROTR register must be set before issuing a programming command. To switch between enabling and disabling of
the lock bits, the setting of the FPROTR register must be changed.
Issuing a programming command while the FACI internal data buffer is full leads to a wait on the peripheral bus 6, and
this may affect the communications performance of other peripheral IP modules. To avoid the generation of a wait in this
way, the FSTATR.DBFULL flag should be 0 when an FACI command is issued.
Writing to the data area will not lead to the data buffer becoming full.
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6. FACI Commands
Start
When switching between enabling and disabling
of the lock bits is required
Set the FPROTR register
Set the first address of the target
block to the FSADDR register
Write E8h
to the FACI command-issuing area
N
Write N
to the FACI command-issuing area 80h: Code flash memory
02h: Data flash memory
Write first 2 bytes of data
to the FACI command-issuing area
n=1
n=n+1
Write next 2 bytes of data
to the FACI command-issuing area
n = N - 1?
No
Yes
DBFULL flag?
0
1
Write D0h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 1.1 times 256-byte programming time (max) for code flash memory.
For data flash memory, judgment is based on 1.1 times 4-byte programming time (max).
For the 256-byte programming time and 4-byte programming time, see the User’s Manual: Hardware.
Figure 6.9
Usage of the Programming Command
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6.3.9
6. FACI Commands
Block Erase Command
A block erase command is used to erase the user area, lock bit, and data area.
Before issuing a block erase command, set the first address of the target block in the FSADDR register. Writing 20h and
D0h to the FACI command-issuing area starts processing of a block erase command.
The FPROTR and FCPSR registers must be set before issuing the block erase command. To switch between enabling and
disabling of the lock bits, the setting of the FPROTR register must be changed. To erase the lock bit, issue a block erase
command while the FPROTR.FPROTCN bit is 1. The setting of the FCPSR register must be changed to switch the
suspending method (suspension priority mode/erasure priority mode) by the P/E suspend command.
Start
Set the FPROTR register
Set the FCPSR register
When switching between enabling and disabling
of the lock bits is required
Set the erasure suspension mode
Set the first address of the target
block to the FSADDR register
Write 20h
to the FACI command-issuing area
Write D0h
to the FACI command-issuing area
FRDY flag?
1
Check the CMDLK flag
0
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 1.1 times 256-byte erasure time (max) for code flash memory.
For data flash memory, judgment is based on 1.1 times 64-byte erasure time (max).
For the 256-byte erasure time and 64-byte erasure time, see the User’s Manual: Hardware.
Figure 6.10
Usage of the Block Erase Command
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6.3.10
6. FACI Commands
P/E Suspend Command
To suspend programming/erasure, use the P/E suspend command.
Before issuing a P/E suspend command, check that the FASTAT.CMDLK flag is 0, and the execution of programming/
erasure is normally performed. To confirm that the P/E suspend command can be received, also check that the
FSTATR.SUSRDY flag is 1. After issuing a P/E suspend command, read the FASTAT.CMDLK flag to confirm that its
value is 0 (the flash sequencer is not in the command-locked state).
If an error occurs during programming/erasure, the FASTAT.CMDLK flag is set to 1. When programming/erasure
processing has finished during the interval from when the FSTATR.SUSRDY flag is checked as 1 to when a P/E suspend
command is received, no error occurs and the suspended state is not entered (the FSTATR.SUSRDY flag is 1 and the
ERSSPD and PRGSPD flags in FSTATR are 0).
When a P/E suspend command is received and then the programming/erasure suspend processing finishes normally, the
flash sequencer enters the suspended state, the FSTATR.SUSRDY flag is set to 1, and the ERSSPD or PRGSPD flag in
the FSTATR register is 1. After issuing a P/E suspend command, check that the ERSSPD or PRGSPD flag in the
FSTATR register is 1 and the suspended state is entered, and then decide the subsequent flow. If a P/E resume command
is issued in the subsequent flow although the suspended state is not entered, an illegal command error occurs and the
flash sequencer shifts to the command-locked state (see section 7.2, Error Protection).
If the erasure suspended state is entered, programming to blocks other than an erasure target can be performed.
Additionally, the programming and erasure suspended states can shift to read mode by clearing the FENTRYR register.
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6. FACI Commands
Start
Command lock
Error check
Other than command lock
SUSRDY flag?
0
1
Issue a status clear
or forced stop command
FRDY flag?
0
Write B0h
to the FACI command-issuing area
Command lock
Error check
Other than command lock
FRDY flag?
1
Check the ERSSPD, PRGSPD
and CMDLK flags
0
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 1.1 times the suspend delay time during erasure (max) for both code
flash memory and data flash memory.
For the suspend delay time during erasure, see the User’s Manual: Hardware.
Figure 6.11
Usage of the P/E Suspend Command
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(1)
6. FACI Commands
Suspension during Programming
When issuing a P/E suspend command during the flash memory programming, the flash sequencer suspends
programming processing. Figure 6.12 shows the suspend operation of programming. When receiving a programmingrelated command, the flash sequencer clears the FSTATR.FRDY flag to 0 to start programming. If the flash sequencer
enters the state in which the P/E suspend command can be received after starting programming, it sets the
FSTATR.SUSRDY flag to 1. When a P/E suspend command is issued, the flash sequencer receives the command and
clears the FSTATR.SUSRDY flag to 0. If the flash sequencer receives a P/E suspend command while a programming
pulse is being applied, the flash sequencer continues applying the pulse. After the specified pulse application time, the
flash sequencer finishes pulse application, and starts the programming suspend processing and sets the
FSTATR.PRGSPD flag to 1.
When the suspend processing finishes, the flash sequencer sets the FSTATR.FRDY flag to 1 to enter the programming
suspended state. When receiving a P/E resume command in the programming suspended state, the flash sequencer clears
the FSTATR.FRDY and FSTATR.PRGSPD flags to 0 and resumes programming.
FACI command
P
S
R
FRDY flag
SUSRDY flag
PRGSPD flag
Programming pulse
Pulse application continues
P: Programming-related command (programming, P/E resume)
S: P/E suspend command
R: P/E resume command
Figure 6.12
Suspension during Programming
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6. FACI Commands
Suspension during Erasure (Suspension Priority Mode)
The RX64M Group has a suspension priority mode for the suspension of erasure. Figure 6.13 shows the suspend
operation of erasure when the erasure suspend mode is set to the suspension priority mode (the FCPSR.ESUSPMD bit is
0).
When receiving an erasure-related command, the flash sequencer clears the FSTATR.FRDY flag to 0 to start erasure. If
the flash sequencer enters the state in which the P/E suspend command can be received after starting erasure, it sets the
FSTATR.SUSRDY flag to 1. When a P/E suspend command is issued, the flash sequencer receives the command and
clears the FSTATR.SUSRDY flag to 0. When receiving a suspend command during erasure, the flash sequencer starts the
suspend processing and sets the FSTATR.ERSSPD flag to 1 even if it is applying an erasure pulse. When the suspend
processing finishes, the flash sequencer sets the FSTATR.FRDY flag to 1 to enter the erasure suspended state. When
receiving a P/E resume command in the erasure suspended state, the flash sequencer clears the FRDY and ERSSPD flags
in the FSTATR register to 0 and resumes erasure. Operations of the FRDY, SUSRDY, and ERSSPD flags in the FSTATR
register at the suspension and resumption of erasure are the same, regardless of the erasure suspend mode.
The setting of the erasure suspend mode affects the control method of erasure pulses. In suspension priority mode, when
receiving a P/E suspend command while erasure pulse A that has never been suspended in the past is being applied, the
flash sequencer suspends the application of erasure pulse A and enters the erasure suspended state. When receiving a P/E
suspend command while reapplying erasure pulse A after erasure is resumed by a P/E resume command, the flash
sequencer continues applying erasure pulse A. After the specified pulse application time, the flash sequencer finishes
erasure pulse application and enters the erasure suspended state. When the flash sequencer receives a P/E resume
command next and erasure pulse B starts to be newly applied, and then the flash sequencer receives a P/E suspend
command again, the application of erasure pulse B is suspended. In suspension priority mode, delay due to suspension
can be minimized because the application of an erasure pulse is suspended one time per pulse and priority is given to the
suspend processing.
FACI command
E
S
R
S
R
S
FRDY flag
SUSRDY flag
ERSSPD flag
Erasure pulse
Pulse A application halted
Pulse A application continues
Pulse B application halted
E: Erasure-related command (block erase, P/E resume)
S: P/E suspend command
R: P/E resume command
Figure 6.13
Suspension during Erasure (Suspension Priority Mode)
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6. FACI Commands
Suspension during Erasure (Erasure Priority Mode)
The RX64M Group has an erasure priority mode for the suspension of erasure.
Figure 6.14 shows the suspend operation of erasure when the erasure suspend mode is set to the erasure priority mode
(the FCPSR.ESUSPMD bit is 1). The control method of erasure pulses in erasure priority mode is the same as that of
programming pulses for the programming suspend processing.
If the flash sequencer receives a P/E suspend command while an erasure pulse is being applied, the flash sequencer
definitely continues applying the pulse. In this mode, the required time for the whole erasure processing can be reduced
as compared with the suspension priority mode because the reapplication of erasure pulses does not occur when a P/E
resume command is issued.
FACI command
E
S
R
FRDY flag
SUSRDY flag
ERSSPD flag
Erasure pulse
Pulse A application continues
E: Erasure-related command (block erase, P/E resume)
S: P/E suspend command
R: P/E resume command
Figure 6.14
Suspension during Erasure (Erasure Priority Mode)
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6.3.11
6. FACI Commands
P/E Resume Command
To resume suspended programming or erasure, use the P/E resume command. When the settings of the FENTRYR
register are changed during suspension, reset FENTRYR to the value immediately before the P/E suspend command was
issued, and then issue a P/E resume command.
Start
Write D0h
to the FACI command-issuing area
0
FRDY flag?
Timeout?*1
1
No
Yes
Issue
a forced stop command
Check the CMDLK flag
End
Note 1. Judgment of the timeout is based on 1.1 times the maximum time for halted processing of the FACI command
(see section 9., Electrical Characteristics).
Figure 6.15
6.3.12
Usage of the P/E Resume Command
Status Clear Command
The status clear command is used to clear the command-locked state (see section 6.3.7, Recovery from the
Command-Locked State). To clear the ILGLERR, ERSERR, and PRGERR flags in the FSTATR register in the
command-locked state, the status clear command is available. All processing of a status clear command can be executed
by hardware without intervention by the FCU firmware.
Start
Write 50h
to the FACI command-issuing area
End
Figure 6.16
Usage of the Status Clear Command
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6.3.13
6. FACI Commands
Forced Stop Command
The forced stop command forcibly ends command processing by the flash sequencer. Although this command halts
command processing more quickly than the P/E suspension command, values from the area where programming or
erasure was in progress are not guaranteed. Furthermore, resumption of processing is not possible. Processing of
programming or erasure that was halted by the forced stop command is also defined as one round of programming.
Executing a forced stop command also initializes part of the FACI, the whole FCU, and the FSTATR. Accordingly, this
command can be used in the procedure for recovery from the command-locked state and in processing in response to a
time-out of the flash sequencer (see section 6.3.7, Recovery from the Command-Locked State)
All processing of a forced stop command can be executed by hardware without intervention by the FCU firmware.
Start
Write B3h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
End
Figure 6.17
Usage of the Forced Stop Command
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6.3.14
6. FACI Commands
Blank Check Command
Values read from data flash memory that has been erased but not yet been programming again (i.e. that is in the nonprogrammed state) are undefined. Use the blank check command when you need to confirm that an area is in the nonprogrammed state.
Before issuing a blank check command, set addressing mode, start address, and end address of the target area for blank
checking to the FBCCNT, FSADDR, and FEADDR registers. When blank checking addressing mode is set to
decremental mode (i.e. FBCCNT.BCDIR = 1), address specified in FSADDR should be larger than address in FEADDR.
Conversely, address in FSADDR should be smaller than address in FEADDR when blank check addressing mode is set
to incremental mode (i.e. FBCCNT.BCDIR = 0).
If the settings of the FBCCNT.BCDIR bit, FSADDR, and FEADDR are inconsistent, the flash sequencer enters the
command-locked state. The size of the target area for blank checking is in the range from 4 bytes to 64 Kbytes and is set
in units of 4 bytes.
Write 71h and D0h to the FACI command-issuing area to start blank checking. Completion of processing can be
confirmed by the FSTATR.FRDY flag. At the end of processing, the result of blank checking is stored in the
FBCSTAT.BCST flag. If the target area for blank checking includes areas where programming has been completed, the
flash sequencer stores the address of the first such area it detects in the FPSADDR register.
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6. FACI Commands
Start
Set the addressing mode
in the FBCCNT register
00h: (Address incremental mode) FSADDR  FEADDR
01h: (Address decremental mode) FSADDR  FEADDR
Set the start address of the area to be
checked in the FSADDR register
Set the end address of the area to be
checked in the FEADDR register
Write 71h
to the FACI command-issuing area
Write D0h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
Check the BCST flag and the
FPSADDR register
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 1.1 times the blank checking time (max.) for the entire target area.
For the blank checking time, see the User’s Manual: Hardware.
Figure 6.18
Usage of the Blank Check Command
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6.3.15
6. FACI Commands
Configuration Set Command
The configuration set command is used to set the ID, security function, option-setting memory, and TM function. Before
issuing a configuration set command, set the specified address (shown in Table 6.5) in the FSADDR register. Writing
D0h to the FACI command-issuing area in the final access for issuing the FACI command starts processing of the
configuration set command.
Start
Set the specified address
to the FSADDR register
Write 40h
to the FACI command-issuing area
Write 08h
to the FACI command-issuing area
Write first 2 bytes of data
to the FACI command-issuing area
n=1
n=n+1
Write next 2 bytes of data
to the FACI command-issuing area
n = 7?
No
Yes
Write D0h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 70 ms elapsing (when FCLK  20 MHz).
Figure 6.19
Usage of the Configuration Set Command
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6. FACI Commands
The correspondence between the possible target data for configuration setting and the address value set in the FSADDR
register is shown in Table 6.5. For details on the FSADDR register, see section 4.5, FACI Command Start Address
Register (FSADDR). Data in other areas can be changed to any value each time the configuration set command is
executed.
Table 6.5
Address Used by Configuration Set Command
Address
FSADDR
Register Value Setting Data
0012 0040h
0000 0040h
Serial programmer command control register (SPCC), TM enable flag register (TMEF)
0012 0050h
0000 0050h
ID for authentication (OSIS)
0012 0060h
0000 0060h
TM identification data register (TMINF), option function selection (OFS0, OFS1), endian selection
(MDE)
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6.3.16
6. FACI Commands
Lock-Bit Programming Command
To write to a lock bit, use the lock-bit programming command. To erase a lock bit, use the block erase command (see
section 6.3.9, Block Erase Command).
Before issuing a lock-bit programming command, set the first address of the target block in the FSADDR register.
Writing 77h and D0h to the FACI command-issuing area starts processing of a lock-bit programming command.
The FPROTR register must be set before issuing a lock-bit programming command. To switch between enabling and
disabling of the lock bits, the setting of the FPROTR register must be changed.
Start
Set the FPROTR register
When switching between enabling and disabling
of the lock bits is required
Set the first address of the target
block in the FSADDR register
Write 77h
to the FACI command-issuing area
Write D0h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 25 ms elapsing (when FCLK  20 MHz).
Figure 6.20
Usage of the Lock-Bit Programming Command
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6.3.17
6. FACI Commands
Lock-Bit Read Command
To read a lock bit, use the lock-bit read command. Before issuing a lock-bit read command, set the first address of the
target block in the FSADDR register.
Writing 71h and D0h to the FACI command-issuing area starts processing of a lock-bit read command.
Completion of command processing can be confirmed with the FSTATR.FRDY flag. After command processing is
completed, the result of reading the lock bit is stored in the FLKSTAT.FLOCKST flag.
Start
Set the start address of the target
block in the FSADDR register
Write 71h
to the FACI command-issuing area
Write D0h
to the FACI command-issuing area
FRDY flag?
0
1
Check the CMDLK flag
Check the FLOCKST flag
Timeout?*1
No
Yes
Issue
a forced stop command
End
Note 1. Judgment of the timeout is based on 10 μs elapsing (when FCLK  20 MHz).
Figure 6.21
Usage of the Lock-Bit Read Command
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7.
Safety Function
7.1
Software Protection
7. Safety Function
Software protection disables programming and erasure for the code flash memory through the settings of control
registers and lock bit settings in the user area. If an attempt is made to issue an FACI command against software
protection, the flash sequencer enters the command-locked state.
7.1.1
Protection through FWEPROR
Unless the FWEPROR.FLWE[1:0] bits are set to 01b, programming cannot proceed in any mode.
7.1.2
Protection through FENTRYR
When the FENTRYR register is set to 0000h, the flash sequencer enters read mode. In read mode, FACI commands
cannot be accepted. If an attempt is made to issue an FACI command in read mode, the flash sequencer enters the
command-locked state.
7.1.3
Protection through Lock Bit
Each block in the user area includes a lock bit. When the FPROTR.FPROTCN bit is 0, blocks whose lock bit is set to 0
are prohibited from being programmed/erased. To program or erase blocks whose lock bit is set to 0, set the
FPROTR.FPROTCN bit to 1. When the lock bit protection is violated and a code flash memory programming, block
erase or lock-bit programming command is issued, the flash sequencer enters the command-locked state.
7.2
Error Protection
Error protection detects the issuing of illegal FACI commands, illegal access, and flash sequencer malfunction. FACI
command acceptance is disabled (command-locked state) in response to the detection of these errors. The flash memory
cannot be programmed or erased while the flash sequencer is in the command-locked state. For release from the
command-locked state, issue a status clear or forced stop command while the CFAE and DFAE flags in the FASTAT
register are 0. The status clear command can only be used while the FSTATR.FRDY flag is 1. The forced stop command
can be used regardless of the value of the FSTATR.FRDY flag. While the FAEINT.CMDLKIE bit is 1, a flash access
error (FIFERR) interrupt is generated if the flash sequencer enters the command-locked state (the FASTAT.CMDLK flag
is set to 1).
If the flash sequencer enters the command-locked state in response to a command other than the P/E suspend command
during programming or erasure processing, the flash sequencer continues the processing for programming or erasure. In
this state, the P/E suspend command cannot be used to suspend the processing for programming or erasure. If a command
is issued in the command-locked state, the FASTAT.ILGLERR flag becomes 1 and the other bits retain the values set due
to previous error detection.
Table 7.1 shows error protection types and status bit values after error detection.
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RX64M Group, RX71M Group Flash Memory
Error Type
Description
ERSERR
PRGERR
FCUERR
FLWEERR
CFGDTCT
TBLDTCT
FRDTCT
CFAE
DFAE
Error Protection Type
ILGLERR
Table 7.1
7. Safety Function
FENTRYR
setting error
The FENTRYR setting is other than 0001h and 0080h.
1
0
0
0
0
0
0
0
0
0
The FENTRYR setting at suspension disagrees with that at
resumption.
1
0
0
0
0
0
0
0
0
0
Illegal
command error
An undefined code is written in the first access of an FACI
command.
1
0
0
0
0
0
0
0
0
0
The value specified in the last access of the multiple-access
FACI command is not D0h.
1
0
0
0
0
0
0
0
0
0
The value (N) specified in the second write access of an FACI
command in the programming or configuration setting command
is wrong.
1
0
0
0
0
0
0
0
0
0
A blank check command has been issued with inconsistent
FBCCNT.BCDIR bit, FSADDR register, and FEADDR register
settings (see section 4.6, FACI Command End Address Register
(FEADDR)).
1
0
0
0
0
0
0
0
0
0
An FACI command not acceptable in each mode has been
issued (see Table 6.3).
1
0
0
0
0
0
0
0
0
0
An FACI command has been issued when command acceptance
conditions are not satisfied (see Table 6.4).
1
An error occurs during erasure.
0
1
0
0
0
0
0
0
0
0
A block erase command has been issued against lock bit
protection.
0
1
0
0
0
0
0
0
0
0
Programming
error
An error occurs during programming.
0
0
1
0
0
0
0
0
0
0
A programming or lock-bit programming command has been
issued against lock bit protection.
0
0
1
0
0
0
0
0
0
0
FCU error
An error occurs during CPU processing in FCU.
0
0
0
1
0
0
0
0
0
0
FCURAM
ECC error
A 2-bit error has been detected when FCURAM is read.
0
0
0
0
0
0
0
1
0
0
Code flash
access
violation
An FACI command has been issued to the reserved portion of
the user area in code flash memory P/E mode (see section 4.2,
Flash Access Status Register (FASTAT)).
1
0
0
0
0
0
0
0
1
0
Data flash
access
violation
An FACI command has been issued to the reserved portion of
the data area in data flash memory P/E mode (see section 4.2,
Flash Access Status Register (FASTAT)).
1
0
0
0
0
0
0
0
0
1
A configuration set command has been issued to the reserved
area (see section 4.2, Flash Access Status Register (FASTAT)).
1
0
0
0
0
0
0
0
0
1
The FACI command-issuing area has been accessed in read
mode.
1
0
0
0
0
0
0
0
0
0
The FACI command-issuing area has been read in code flash
memory P/E mode or data flash memory P/E mode.
1
0
0
0
0
0
0
0
0
0
Flash write
erase
protection error
A flash memory write protection error has been detected by the
setting of the FWEPROR register*1 during command processing
by the flash sequencer.
0
0
1
0
0
0
0
0
Configuration
set ECC error
A 2-bit error has been detected when the configuration setting
value is read.
0
0
0
0
0
1
0
0
0
0
Programming
parameter
ECC error
A 2-bit error has been detected when the overwrite parameter
table is read.
0
0
0
0
0
0
1
0
0
0
Erasure error
Others
0/1 0/1 0/1 0/1 0/1 0/1 0/1 0/1 0/1
0/1 0/1
Note 1. For details on the FWEPROR register, see section 4.1, Flash P/E Protect Register (FWEPROR).
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Jan 15, 2015
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RX64M Group, RX71M Group Flash Memory
7.3
7.3.1
7. Safety Function
Boot Program Protection
User Boot Protection
The user boot area can only be overwritten in programming mode (boot mode (for the SCI or USB interface)). Since this
area is usually write-protected in normal operating mode and user boot mode, it can be used for the safe storage of
programs such as a boot program.
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Jan 15, 2015
Page 61 of 67
RX64M Group, RX71M Group Flash Memory
8.
(1)
8. Usage Notes
Usage Notes
Reading areas where programming or erasure was interrupted
When programming or erasure of an area of flash memory is interrupted, the data stored in the area become undefined.
To avoid undefined data that are read out becoming the source of faulty operation, take care not to fetch instructions or
read data from areas where programming or erasure was interrupted.
(2)
Prohibition of additional writing
Writing to a given area twice is not possible. If you want to overwrite data in an area of flash memory after writing to the
area has been completed, erase the area first.
(3)
Resets during programming and erasure
In the case of a reset due to the signal on the RES# pin during programming and erasure, wait for at least tRESWF (see the
User's Manual: Hardware for details) once the operating voltage is within the range stipulated in the electrical
characteristics after assertion of the reset signal before releasing the device from the reset state.
(4)
Allocation of vectors for interrupts and other exceptions during programming and erasure
Generation of an interrupt or other exception during programming or erasure may lead to fetching of the vector from the
code flash memory. If this does not satisfy the conditions for using background operation, set the address for vector
fetching to an address that is not in the code flash memory.
(5)
Abnormal termination of programming and erasure
Even if programming/erasure ends abnormally due to the generation of a reset by the RES# pin, the programming/
erasure state of the flash memory with undefined data cannot be verified or checked. For the area where programming/
erasure ends abnormally, the blank check function cannot judge whether the area is erased successfully or not. Erase the
area again to prove that the corresponding area is completely erased before using.
If programming and erasure of code flash memory are not completed normally, the lock bit for the target area may be
enabled (locked). In such cases, erase the block to erase the lock bit while the lock bit is in the disabled state (the area is
not locked).
(6)
Items prohibited during programming and erasure
Do not perform the following operations during programming and erasure.
 Have the operating voltage from the power supply go beyond the allowed range.
 Change the frequency of the PCLK/FCLK.
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Jan 15, 2015
Page 62 of 67
RX64M Group, RX71M Group Flash Memory
9.
Electrical Characteristics
9.1
AC Characteristics
9. Electrical Characteristics
Conditions: VCC = AVCC0 = AVCC1 = VCC_USB = VBATT = 2.7 to 3.6 V, 2.7 ≤ VREFH0 ≤ AVCC0,
VCC_USBA = AVCC_USBA = 3.0 to 3.6 V,
VSS = AVSS0 = AVSS1 = VREFL0 = VSS_USB = VSS1_USBA = VSS2_USBA = PVSS_USBA = AVSS_USBA = 0 V,
Ta = Topr
Item
Min.
Typ.
Max.
Unit
Conditions
FCURAM data transfer time
—
220
—
μs
FCLK = 60 MHz and the FRAMTRAN bit in the FCURAME
register is 0
—
110
—
μs
FCLK = 60 MHz and the FRAMTRAN bit in the FCURAME
register is 1
FACI command setup time
—
—
100
μs
FCLK ≥ 20 MHz
FACI command proccessing time
—
—
0
tFcyc
For other than programming of code flash memory
—
—
90
tFcyc
For programming of code flash memory
—
—
20
μs
20MHz ≤ FCLK ≤ 60MHz
—
—
32
μs
FCLK = 4MHz
Forced stop command
Note:
tFcyc: PCLKB/FCLK cycle
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Jan 15, 2015
Page 63 of 67
REVISION HISTORY
RX64M Group, RX71M Group Flash Memory
REVISION HISTORY
REVISION HISTORY RX64M Group Flash Memory User’s Manual: Hardware Interface
Rev.
Date
0.90
May 30, 2014
1.00
Jul 31, 2014
1.10
Nov 05, 2014
Page
—
Description
Summary
First edition, issued
6. FACI Commands
8
Table 3.1 Information on the Hardware Interface Area, changed
32
Table 6.1 List of FACI Commands, changed
55
6.3.15 Configuration Set Command, changed
56
Table 6.5 Address Used by Configuration Set Command, changed
60
Table 7.1 Error Protection Type, changed
—
RX71M group, added
All
Terms unified:
RX64M User’s Manual: Hardware or RX71M User’s Manual: Hardware → User’s Manual: Hardware
1. Features
6
Body text changed
2. Module Configuration
7
Body text changed
4. Registers
10
4.1 Flash P/E Protect Register (FWEPROR), changed
11
4.2 Flash Access Status Register (FASTAT), changed
13
4.3 Flash Access Error Interrupt Enable Register (FAEINT)
15
4.5 FACI Command Start Address Register (FSADDR), changed
16
4.6 FACI Command End Address Register (FEADDR), changed
17
4.7 FCURAM Enable Register (FCURAME), changed
22
4.9 Flash P/E Mode Entry Register (FENTRYR), changed
23
4.10 Flash Protection Register (FPROTR), changed
24
4.11 Flash Sequencer Set-Up Initialization Register (FSUINITR), changed
27
4.14 Flash P/E Status Register (FPESTAT), changed
30
4.19 Flash Sequencer Processing Clock Notification Register (FPCKAR), changed
6. FACI Commands
32
Table 6.1 List of FACI Commands, changed
33
6.2 Relationship between the Flash Sequencer State and FACI Commands, changed
35
Figure 6.1 Overview of Command Usage in Code Flash Memory P/E Mode (for products in which
BGO is possible), changed
36
Figure 6.2 Overview of Command Usage in Code Flash Memory P/E Mode (for products in which
BGO is not possible), changed
37
Figure 6.3 Overview of Command Usage in Data Flash Memory P/E Mode, changed
40
Figure 6.7 Procedure for Transition to Read Mode, changed
44
Figure 6.9 Usage of the Programming Command, changed
46
6.3.10 P/E Suspend Command, changed
48
Figure 6.12 Suspension during Programming, changed
54
Figure 6.18 Usage of the Blank Check Command, changed
55, 56
6.3.15 Configuration Set Command, changed
Table 6.5 Address Used by Configuration Set Command, changed
7. Safety Function
59
7.1.3 Protection through Lock Bit, changed
60
Table 7.1 Error Protection Type, changed
8. Usage Notes
62
(3) Resets during programming and erasure, changed
R01UH0435EJ0110 Rev.1.10
Jan 15, 2015
Page 64 of 67
Colophon
RX64M Group, RX71M Group User’s Manual: Hardware Interface
Publication Date:
Rev.0.90
Rev.1.10
May 30, 2014
Jan 15, 2015
Published by:
Renesas Electronics Corporation
http://www.renesas.com
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RX64M Group, RX71M Group Flash Memory
R01UH0435EJ0110